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Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8555-8558 8555 
 

www.etasr.com Al-Khazaal & Ahmad: A Study of the Impact of Iron Content on the Thermal Response of the sPP/Fe … 

 

A Study of the Impact of Iron Content on the Thermal 

Response of the sPP/Fe Composites 
 

Abdulaal Z. Al-Khazaal 

Department of Chemical and Material Engineering 
Northern Border University 

Arar, Saudi Arabia 

abdulaal.alkhazaal@nbu.edu.sa 

Naveed Ahmad 

Department of Chemical and Material Engineering 
Northern Border University 

Arar, Saudi Arabia 

naveed.ahmad@nbu.edu.sa 
 

Received: 6 March 2022 | Revised: 24 March 2022 | Accepted: 29 March 2022 

 

Abstract-A set of syndiotactic polypropylene/iron (sPP/Fe) 

composite samples were manufactured with the extrusion 
technique to study the impact of iron content on the thermal 

behavior of sPP/Fe composites in the melt phase. The dosage of 

iron contents varied from 0 to 8%. Melting point (Tm), 

crystallization temperature (Tc), and thermal degradation 

temperature (Td) were measured by Differential Scanning 

Calorimetry (DSC) and Thermal Gravimetric Analysis (TGA) for 

each composite sample. Thermal temperatures (Tm, Tc, and Td) 
increased with increasing the iron contents due to the 

enhancement of the strength and thermal stability of the sample. 

This investigation is a validated fact that fillers (iron) alter both 

the macroscopic and microscopic properties of the polymer 
composites. 

Keywords-thermal properties; DSC; TGA; polymer composites; 
thermal degradation temperature 

I. INTRODUCTION  

Polymer composites have become one of the most 
important manufactured materials and can be industrialized by 
the incorporation of filler (natural or synthetic) into the 
polymer to improve its targeted properties [1-5]. Polymer 
composites with different types of fillers and combinations are 
widely used with improved mechanical, thermal, barrier and 
fire resistant properties for different applications [6-8]. 
However, the end desired microstructure and macrostructure 
properties of polymer composites are greatly dependent on the 
nature, amount, geometry and interfacial interactions of the 
components [9]. The thermal properties are highly dependent 
and sensitive to microstructure properties of polymer and 
polymer composites [10-14]. Therefore, the relationship of the 
thermal response and microstructure properties is an excellent 
key in both the process and quality control to realize and 
develop new materials with the desired properties. Thermal 
properties can be used in the understanding of molecular 
structure and the link with both microstructure and 
macrostructure properties [6, 7, 15-18]. Some of the recent 
scientific advances in the iron/polymer and its properties are 
mentioned below. 

Authors in [19] investigated the thermal properties 
including thermal conductivity, thermal diffusivity, and 

specific heat of metal (copper, zinc, iron, and bronze) powder-
filled high-density polyethylene composites experimentally in 
the range of filler content 0-24%. They found a region of low 
particle content (0-16%), where the particles are embedded 
homogeneously in the polymer matrix and do not interact with 
each other. Fillers at higher content regions, tend to accumulate 
and conductive chains result in a quiche enhancement in 
thermal conductivity. Authors in [20] studied the thermo-
mechanical properties of polymer/metal composites. The 
Acrylonitrile Butadiene Styrene (ABS) was used as a matrix 
and copper and iron particles as fillers. The effect of metal 
powder was studied to confirm the effects of metal particles on 
the thermo-mechanical properties of the composites, such as 
tensile strength and thermal conductivity. It was found that the 
tensile strength of the composites decreases with increasing 
loading of the metal particles, while the thermal conductivity of 
the metal/polymer composite filament was found to improve by 
increasing metal content. More recently, authors in [21] 
examined the electrical and thermal conductivity of the ternary 
epoxy composites (CMs) with two-component fillers, multiwall 
carbon nanotubes (MWCNT)/TiO2, and MWCNT/carbonyl 
iron (Fe). Both electrical and thermal properties were found 
sensitive to both fillers. However, MWCNT/TiO2 or 
MWCNT/Fe into epoxy supports smaller changes in thermal 
conductivity as compared to the two-phase MWCNT/epoxy 
composites. 

To the best of our knowledge, the understanding of the 
thermal properties of syndiotactic polypropylene/Iron (sPP/Fe) 
has not been established by now. Thus, in the present work, 
sPP/Fe composites with different iron dosages were 
investigated to study the influence of iron content on the 
thermal properties of the composites, including melting point 
temperature (Tm), crystallization temperature (Tc), and thermal 
degradation temperature (Td).  

II. METHEDOLOGY 

A. Experimental Work 

1) Materials 

Polymer composites were prepared using Syndiotactic 
polypropylene (sPP) and iron (Fe) with content variety as a 

Corresponding author: Abdulaal Z. Al-Khazaal 



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www.etasr.com Al-Khazaal & Ahmad: A Study of the Impact of Iron Content on the Thermal Response of the sPP/Fe … 

 

filler. Zhongwei Industrial Co. Ltd supplied the polymer with 
60% degree of syndiotacticity, and Sigma Aldrich provided the 
iron in powder form. Five samples were prepared with Fe 
content varying from 0 to 8% with a step size of 2%.  

2) Preparation of Polymer Composites  

The extrusion technique was used to formulate a set of 
sPP/Fe composites with different percentages of Fe as shown in 
Table I. For each sample, at first the required amount of Fe was 
dried in an oven at 75°C for 24 hours, and then it was 
accurately weighed. After that, when the extruder reached 
250°C, both polypropylene and the required amount of iron 
entered the extruder for mixing to prepare the composite 
samples. The size of the prepared polymer-iron composite 
sample was mechanically reduced to suitable size before 
completely dried. Then, a film of the composite sample was 
prepared by compression molding at 170°C and 7Psi pressure 
for the duration of 1 hour using Hot Press. 

B. Analytical Work 

Differential Scanning Calorimetry (DSC) and Thermal 
Gravimetric Analysis (TGA) were conducted to investigate the 
influence of iron content on the thermal behavior of the sPP/Fe 
composites. 

1) Differential Scanning Calorimetry 

The melting temperature (Tm) of all samples was 
determined by DSC using non-isothermal crystallization tests. 
Two main cycles (heating and cooling) were used in this 
technique. In the heating cycle, the sample having a weight of 
4mg was heated up to 200°C at a constant heating rate of 
10°C/min. After the melting point peak was obtained, the 
sample was kept under this annealing process for 5 minutes in 
order to eliminate the crystallinity and remove thermal history. 
During the cooling cycle, the DSC temperature was decreased 
up to -130°C with a cooling rate of -10°C/min. Therefore, the 
peaks of crystallinity and glassy behavior of the composites 
were observed. Evaluations were made using the instrument 
software TA-60 to estimate the melting temperature (Tm) and 
crystallization temperature (Tc) of all the samples. 

2) Thermal Gravimetric Analysis 

Thermal degradation temperature (Td) shows the maximum 
temperature at which a polymer is useful. In this investigation, 
the thermal degradation temperature of all composites was 
measured using TGA. This analysis was conducted by 
observing the drop in the mass of the composite sample. In the 
beginning of the analysis, the sample was weighed, and then 
loaded to the equipment and heated up to 600

o
C. During the 

heating process, the polymer started to burn at a certain 
temperature where the fall in the mass of samples was 
observed. The obtained results were analyzed with TA-60 for 
each sample. 

III. RESULTS AND DISCUSSION 

Table I expresses the thermal information of all polymer 
composites extracted from DSC and TGA. The number shown 
in the sample ID represents the percentage of sPP and Fe in 
each composite sample.  

TABLE I. THERMAL TEMPERATURES OF THE COMPOSITE SAMPLES 

Sample ID Fe % Tc (°C) Tm (°C) Td (°C) 

PP-Fe-(100-0) 0 113.96 146.72 360 

PP-Fe-(98-02) 2 114.79 147.86 380 

PP-Fe-(96-04) 4 115.76 148.62 395 

PP-Fe-(94-06) 6 116.51 149.71 405 

PP-Fe-(92-08) 8 117.69 150.62 418 

 

A. The Effect of Iron Content on Crystallization Temperature 

DSC determines the heat flow as a function of temperature, 
which is directly related to the latent heat of crystallization. In 
DSC measurements, the temperature at the peak of the 
endothermic heat flow represents the crystallization 
temperature of the composite sample. Fig. 1. Figure 1 
illustrates the experimental results of DSC related to the 
crystallization temperature of each sample. Figure 2 shows the 
relation between the crystallization temperatures of a set of 
composite samples with different Fe content. It was found that 
the increase in Fe content increases the crystallization 
temperature and hence the crystallinity of the composites due 
to the increase of the crystalline phase. 

 

 
Fig. 1.  DSC results (Tc) of all composite samples. 

 
Fig. 2.  Relationship between iron content and crystallization temperature. 

B. The Effect of Iron Content on Melting Point Temperature 

The melting point of all the samples was determined from 
the peak of DSC as displayed in Figure 3. 

0

2

4

6

8

10

12

100 105 110 115 120 125 130 135

m
W

Temperature (oC)

PP-Fe-(100-0)

PP-Fe-(98-02)

PP-Fe-(96-04)

PP-Fe-(94-06)

PP-Fe-(92-08)

113

114

115

116

117

118

0 1 2 3 4 5 6 7 8 9

T
c 
(o
C
)

Fe%



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Fig. 3.  DSC results of all samples showing the melting point peak. 

The influence of Fe content on the melting point of the 
composites was noted. The melting point was found to increase 
with the increase in the Fe content as illustrated in Figure 4. 
This can be related to the fact that an increase in the Fe content 
increases the adhesive properties of the composites and more 
energy is required to break the bonds of monomers. In other 
words, an increase in Fe content increases the latent heat of 
fusion of the composite samples. 

 

 
Fig. 4.  Relationship between the Fe content and the melting point of all 
composite samples. 

C. The Effect of Iron Content on Thermal Degradation 

Temperature 

The Td of sPP/Fe was measured by TGA. Figure 5 displays 
that Td changes with the Fe content of sPP/Fe composites. Td is 
noted from the dropping point of the mass of the sample (the 
point at which the mass of the composites starts to drop). This 
is the maximum point of thermal tolerance of the sample. At 
this point, irreversible changes occur in the sample. We noted 
two drops in the mass of sPP/Fe samples. The first drop 
occurred at relatively low temperature due to the removal of 
moisture content from the sample. The second drop occurred at 
higher temperature, which shows the drop in the mass of the 
sample. 

The relationship between thermal degradation temperature 
and Fe content is presented in Figure 6. The thermal 
degradation temperature increases when Fe content increases. 
The thermal degradation can be related to the fact that Fe 
content enhances the thermal stability of the sPP/Fe 

composites. Td shows the maximum temperature at which a 
polymer is useful. At higher temperatures, the components of 
the long chain of the polymer can disrupt (chain scission) and 
interact with one another (cross-link), thus altering the 
properties of the polymer. 

 

 

Fig. 5.  TGA results of the composite samples. 

 
Fig. 6.  Relationship of Fe content and degradation temperature. 

In the light of the above findings, it is clear that Fe as filler 
alters the thermal properties of sPP/FE composites. The same 
result was found in [17]. The authors found that rheological 
and thermal properties like melting point vary with varying 
filler content. To the best of our knowledge, the thermal 
properties of sPP/FE composites have not yet been studied. 

IV. CONCLUSION 

Thermal properties including melting point, crystallization, 
and thermal degradation temperatures are used as a tool to 
predict not only thermal stability, but also other microstructure 
properties and polymer chain dimensions which affects overall 
polymer chain dynamics. The iron content alters the thermal 
properties of the polymer composites and hence the polymer 
chain dimensions. The experimental results established that 
thermal measurements performed on sPP/Fe composites of 
different iron contents show that melting point, crystallization 
temperature and thermal degradation temperature significantly 
depend on the iron loading. In other words, crystallization, 
melting point, and thermal degradation temperature increase 
with increase in the iron dosage due to the consequently 

-26

-25

-24

-23

-22

-21

-20

-19

-18

-17

130 140 150 160 170 180 190

m
W

Temperture (oC)

PP-Fe-(100-0)

PP-Fe-(98-02)

PP-Fe-(96-04)

PP-Fe-(94-06)

PP-Fe-(92-08)

146

147

148

149

150

151

0 1 2 3 4 5 6 7 8 9

T
m
(o
C
)

Fe (%)

0

20

40

60

80

100

120

300 350 400 450 500

W
e

ig
h

t 
(%

)

Temperature (oC)

PP-FE-(100-0)

PP-FE-(98-02)

PP-Fe-(96-04)

PP-Fe-(94-06)

PP-FE-(92-08)

340

360

380

400

420

440

460

0 1 2 3 4 5 6 7 8 9

T
d

(o
C

)

Fe %



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increased crystallinity, increased latent heat of fusion, and 
increased the thermal stability respectively. 

ACKNOWLEDGMENT 

This research was funded by the Deanship of Scientific 
Research at Northern Border University through the Fast-track 
Research Funding Program (ENG-2018-3-9-F-7595). 

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